Flexible organic light emitting diode (FOLED) is an emerging technology of next-generation display and lighting for its excellent form factor and mobility. However, FLOED suffers a shortcoming that the oxygen and water permeating through plastic substrate at a relatively high rate, can react with the cathode, resulting in severe degradation. Therefore, high WVTR (water vapor transmission rate) performance barrier films with high transmittance and 10,000-hr lifetime are required for FLOED application. In this thesis, a multi-layered structure of SiCxNy/PPMMA (plasma polymerized methyl methacrylate) deposited on flexible PET substrate by PECVD at low temperature has been successfully developed to passivate OLED devices from moisture. In specific, two different precursors, N-Methyl-Aza-2,2,4- trimethylsilacyclopentane (MTSCP) and 1,3,5-trimethyl-1,3,5-trivinylcyclo- trisilazane (VSZ) were used for the deposition of SiCxNy film, while methyl methacrylate and styrene monomer were used as the precursor for PPMMA and plasma-polymerized polystyrene (PPS) films, respectively. The correlation between WVTR and the pinhole density of SiCxNy films using two different precursors were examined. It was found that MTSCP-derived SiCxNy film possessed better barrier effectiveness, i.e. WVTR because of its lower pinhole density compared to VSZ-derived film. Moreover, the WVTR of organic layer, PPMMA film was better than PPS film, due to its higher film density and small moisture solubility. The effect of inorganic/organic layer pairs was further studied to understand their contributions in the lag-time and WVTR. It was found that one additional pair of SiCxNy/PPMMA layers can extend the lag-time by 20% and reduce WVTR significantly within lag-time region, but has less effect in steady-state WVTR region. Three pairs of SiCxNy/PPMMA can reduce WVTR down to 9×10-4 g/m2/day, with a lag-time of 13 hours. The four-pair SiCxNy/PPMMA barrier stack on PET with an estimated WVTR of 5×10-4 g/m2/day was used to passivate an OLED lighting device. At an initial luminance of 4000 cd/m2, the operational half-lifetime was 93.3 hrs and an estimated lifetime of 3200 hrs (133days) at 500 cd/m2 was calculated, which was 70% longer than bare PET passivation.